Traffic Graph Convolutional Network for Dynamic Urban Travel Speed Estimation

The dynamic urban link travel speed estimation (DU-LSE) problem has been studied extensively with approaches ranging from model to data driven since it benefits multiple applications in transport mobility, especially in dense cities. However, with drawbacks such as heavy assumption in model-driven a...

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Bibliographic Details
Published in:Networks and spatial economics 2023-03, Vol.23 (1), p.179-222
Main Authors: Ngo, Huan, Mishra, Sabyasachee
Format: Article
Language:English
Subjects:
Artificial neural networks
Central business districts
Cities
Civil Engineering
Datasets
Deep learning
Economic activity
Economics
Economics and Finance
Infrastructure
Operations Research/Decision Theory
Regional/Spatial Science
Roads & highways
Traffic control
Traffic flow
Traffic models
Transportation planning
Travel
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Summary:The dynamic urban link travel speed estimation (DU-LSE) problem has been studied extensively with approaches ranging from model to data driven since it benefits multiple applications in transport mobility, especially in dense cities. However, with drawbacks such as heavy assumption in model-driven and not being capable for big city network in data-driven, there has not been a consensus on the most effective method. This study aims to develop a Sequential Three Step framework to solve the DU-LSE problem using only the passively collected taxi trip data. The framework makes use of two deep learning models namely Traffic Graph Convolution (TGCN) and its recurrent variant TGCN lstm to capture both spatial and temporal correlation between road segments. The proposed framework has three advantages over similar approaches: (1) it uses only the affordable taxi data and overcomes the data’s incompleteness both in spatial (full GPS trajectory is not available) and temporal (incomplete historic time-series) domain, (2) it is specifically designed to preserve the directionality nature of traffic flow, and (3) it is capable for large networks. The model results and validations suggest the framework can achieve high enough accuracy and will provide valuable mobility data for cities especially those without traffic sensing infrastructure already in place.
ISSN:1566-113X
1572-9427
DOI:10.1007/s11067-022-09582-9